马建 更新日期:2025/7/4 1
马建,男,1986年出生,【学术学位:博士导师,专业学位:博士导师】
工作单位 小麦研究所
电子邮箱 jianma@sicau.edu.cn;plantgbmj@qq.com
招生专业 博士:090102作物遗传育种,095100农业,硕士:090102作物遗传育种,095131农艺与种业
◆个人简历
教授,博士生导师,国家重点研发计划(青年)首席科学家,四川省学术和技术带头人后备人选,四川省海外留学人员,四川农业大学优秀博士学位论文获得者。在International Journal of Biological Macromolecules、Theoretical Applied and Genetics、Crop Journal等国际知名学术期刊发表论文80余篇,ESI高被引论文1篇,副主编专著1部。主持获得四川省自然科学奖二等奖1项(1/5)。主持(研)选育小麦新品种1(6)个。主持获得授权国家发明专利17项。主持国家重点研发计划项目1项、国家自然科学基金项目4项、省厅基金项目10项。担任Molecular Genetics and Genomics 编委、中国农业科学等5个杂志专刊编辑以及SCIENCE CHINA Life Sciences、Theoretical and Applied等40余个杂志审稿人。获得Crop Journal(2021-2023年度)和JIA(2020年度)期刊优秀审稿人和2021全球农业基因与遗传学高产作者。
培养博士毕业生4名、硕士毕业生30名。

近五年指导培养研究生国家奖学金获得者10名、省优毕业生获得者6名、校优秀硕士学位论文获得者1名。

研究生指导方面,近五年合计指导44名(含在读21名)研究生。指导(协助指导)博士5名(1名)、硕士14名(3名)。指导(协助指导)毕业博士1名(1名)、硕士10名(9名),其中4名(2名)提前攻博。毕业博士以引进人才方式进入新疆大学和绵阳师范学院工作。部分毕业硕士考取四川大学和本校博士,部分进入县农业局、地方农科院,从事农业相关工作。10人获研究生国家奖学金,5人获省级优秀毕业研究生,1人获研究生学生标兵提名奖(本单位至今唯一1名),1名硕士毕业生获校级优秀硕士学位论文,2人获校级优秀毕业生,18人次获得校级优秀研究生,5人获得研究生中期考核及开题报告考核优秀。30名研究生参与发表61篇学术论文。14名研究生参与授权国家发明专利16项。17名研究生参与14项国家自然科学基金和省部级项目。13人参与7次国内、国际会议。


个人主页

https://xms.sicau.edu.cn/info/1061/2616.htm


更多了解

https://cbgc.scol.com.cn/news/5449673?from=iosapp&app_id=cbgc

(科技蜀光丨在小麦育种迷宫中找到通往高产宝藏的线索【2024-9-25】)

https://news.sicau.edu.cn/info/1135/77833.htm

(我校15项成果获四川省科学技术奖【2024-9-10】)

https://news.sicau.edu.cn/info/1078/76528.htm

(小麦研究所马建教授应邀参加山东省泰山学术论坛【2024-06-03】)

https://news.sicau.edu.cn/info/1135/76376.htm

(我校3个国家重点研发计划项目联合启动会召开【2024-05-22】)

https://news.sicau.edu.cn/info/1078/76256.htm

(小麦研究所举行粮食安全教育田间科普活动【2024-05-14】)

https://news.sicau.edu.cn/info/1086/74734.htm

(刘航:决心如磐,前行不辍【2023-12-23】)

https://news.sicau.edu.cn/info/1078/74194.htm

(我校4名作物学科学子荣获首届“袁隆平追梦奖学金”【2023-11-09】)

https://news.sicau.edu.cn/info/1078/72048.htm

(李聪:砥砺深耕,笃行致远【2023-04-28】)

https://news.sicau.edu.cn/info/1078/71632.htm

(我与麦苗共成长——川农大小麦研究所科普活动举行【2023-03-31】)

https://news.sicau.edu.cn/info/1086/65683.htm

(莫自强:勤能补拙是良训【2021-11-25】)

https://news.sicau.edu.cn/info/1078/47504.htm

(13位教师喜获2018年度留学回国人员科技活动项目择优资助【2018-08-30】)

https://news.sicau.edu.cn/info/1078/28740.htm

(2015级作物遗传育种硕士研究生的“科研第一课”【2015-09-20】)

https://news.sicau.edu.cn/info/1135/37904.htm

(我校与澳大利亚联邦科学与工业组织签署合作协议【2015-06-02】)

https://news.sicau.edu.cn/info/1078/29405.htm

(马建:保持一颗永不放弃的心【2015-06-24】)
◆教育经历
2005-2009 四川农业大学 本科

2009-2012 四川农业大学小麦研究所 硕士

2012-2014 澳大利亚CSIRO 博士联合培养学习

2012-2015 四川农业大学小麦研究所 博士
◆获奖荣誉
2018年10月 获就业工作先进导师称号
◆研究领域
小麦产量性状基因的定位、分离、功能分析及其育种应用
利用经典遗传学、转录组学和比较基因组学等对控制小麦产量性状(如籽粒大小、小穗数、分蘖数目和角度)位点进行遗传定位、验证、分离和功能分析。同时利用反向遗传学手段分离产量相关性状的同源基因,对其结构、表达及其功能进行解析。最终通过常规育种和基因工程技术培育具有优异基因的小麦品系(种)。
◆科研项目
国家重点研发计划项目
国家自然基金面上项目
国家自然基金青年基金
四川省科技厅应用基础重点项目
四川省教育厅重点项目
四川农业大学人才引进项目
留学回国人员科技活动重点项目
◆发表论文
【主要学术论文】

第一或通讯作者:

[2024]A co-located QTL for seven spike architecture-related traits shows promising breeding use potential in common wheat (Triticum aestivum L.). Theoretical and Applied Genetics. 137: 31.

[2024]Identification and characterization of QSFS.sau-MC-5A for sterile florets genetically independent of fertile ones per spike in wheat. Theoretical and Applied Genetics. 137: 232.

[2024]A novel QTL conferring Fusarium crown rot resistance on chromosome 2A in a wheat EMS mutant. Theoretical and Applied Genetics. 137: 49.

[2024]Integration of transcriptomics, metabolomics, and hormone analysis revealed the formation of lesion spots inhibited by GA and CTK was related to cell death and disease resistance in bread wheat (Triticum aestivum L.). BMC Plant Biology. 24: 558.

[2024]基于遗传解析新模式的小麦寡分蘖QTL的鉴定和验证. 作物学报. 50: 1373-1383.

[2023]Loss of ADP-glucose transporter in barleysex1mutant caused shrunken endosperm but with elevated protein and β-glucan content in whole meal.International Journal of Biological Macromolecules. 251: 126365.

[2023]Major and stably expressed QTL for traits related to the mature wheat embryo independent of kernel size.Theoretical and Applied Genetics. 136: 90.

[2023]A major QTL simultaneously increases the number of spikelets per spike and thousand-kernel weight in a wheat line.Theoretical and Applied Genetics. 136: 213.

[2023]A promising QTL QSns.sau-MC-3D.1 likely superior toWAPO1 for the number of spikelets per spike of wheat shows no adverse effects on yield-related traits.Theoretical and Applied Genetics. 136: 181.

[2023]基于16K SNP芯片的小麦株高QTL鉴定及其遗传分析.中国农业科学. 56: 2237-2248.

[2023]四倍体小麦胚大小性状QTL定位与分析.中国农业科学. 56: 203-216.

[2022]The wheat (Triticum aestiveumL.) MADS-box transcription factorTaMADS32 plays a role in response to abiotic stresses.Biotechnology & Biotechnological Equipment. 36: 451-461.

[2022]Identification and validation of a major QTL for kernel length in bread wheat based on two F3 biparental populations.BMC Genomics. 23: 386.

[2022]A major vernalization-independent QTL for tiller angle on chromosome arm 2BL in bread wheat.The Crop Journal. 10: 185-193.

[2022]Fine mapping of the Hairy glume (Hg) gene in a chromosome variation region at the distal terminus of 1AS.Frontiers in Plant Science. 13: 1006510.

[2022]Identification and validation of a locus for wheat maximum root length independent of parental reproductive environment.Frontiers in Plant Science. 13:995183

[2022]A major quantitative trait locus for wheat total root length associated with precipitation distribution.Frontiers in Plant Science. 13:999414

[2022]A major and stable QTL for wheat spikelet number per spike was validated in different genetic backgrounds.Journal of Integrative Agriculture. 20: 1551–1562.

[2022]Mapping and validation of major and stable QTL for flag leaf size from tetraploid wheat.Plant Genome. e20252.

[2022]Characterization and fine mapping of a lesion mimic mutant (Lm5) with enhanced stripe rust and powdery mildew resistance in bread wheat (Triticum aestivumL.).Theoretical and Applied Genetics. 135: 421-438.

[2022]Quick mapping and characterization of a co-located kernel length and thousand-kernel weight-related QTL in wheat.Theoretical and Applied Genetics. 135: 2849-2860.

[2022]小麦穗发育相关基因的研究进展.四川农业大学学报. 40: 1-9.

[2022]主要植物类病斑突变体研究进展及其对小麦相关研究的启示.四川农业大学学报. 1-20.

[2022]小麦小穗数调控基因WAPO1的单倍型、遗传效应、地理分布及育种利用分析.作物学报.48: 2196-2209.

[2021]Genetic identification and characterization of chromosomal regions for kernel length and width increase from tetraploid wheat.BMC Genomics. 22: 706.

[2021]QTL mapping and validation of bread wheat flag leaf morphology across multiple environments in different genetic backgrounds.Theoretical and Applied Genetics. 134: 261-278.

[2021]A major vernalization-independent QTL for tiller angle on chromosome arm 2BL in bread wheat.The Crop Journal.2021

[2021]The 55K SNP-Based Exploration of QTLs for Spikelet Number Per Spike in a Tetraploid Wheat (Triticum turgidumL.) Population: Chinese Landrace “Ailanmai” × Wild Emmer.Frontiers in Plant Science. 12: 1961.

[2021]Genetic Mapping and Validation of Loci for Kernel-Related Traits in Wheat (Triticum aestivumL.).Frontiers in Plant Science. 12: 667493.

[2021]Genetic dissection of wheat uppermost-internode diameter associated with agronomic traits in five recombination inbred line populations at various field environments.Journal of Integrative Agriculture. 20: 2849–2861.

[2021]A major and stable QTL for wheat spikelet number per spike was validated in different genetic backgrounds.Journal of Integrative Agriculture. 20: 2-13 (doi:10.1016/S2095-3119(1020)63602-63604).

[2021]QTL mapping and validation of bread wheat flag leaf morphology across multiple environments in different genetic backgrounds.Theoretical and Applied Genetics. 134: 261-278.

[2020]Flag leaf size and posture of bread wheat: genetic dissection, QTL validation and their relationships with yield-related traits.Theoretical and Applied Genetics. 133: 297-315.

[2020]A novel, major, and validated QTL for the effective tiller number located on chromosome arm 1BL in bread wheat.Plant Molecular Biology. 104: 173-185.

[2020]Genetic dissection of wheat uppermost-internode diameter associated with agronomic traits in five recombination inbred line populations at various field environments.Journal of Integrative Agriculture. 19: 2-4.

[2020]Transcriptome analysis of near-isogenic lines for glume hairiness of wheat.Gene. 739: 144517.

[2020]Identification and characterization of mRNAs and lncRNAs of a barley shrunken endosperm mutant using RNA-seq.Genetica. 148: 55-68.

[2020]Quantitative trait loci for seeding root traits and the relationships between root and agronomic traits in common wheat.Genome. 63: 27-36.

[2020]Several stably expressed QTL for spike density of common wheat (Triticum aestivum) in multiple environments.Plant Breeding. 139: 284-294.

[2019]Identification of quantitative trait loci for kernel traits in a wheat cultivar Chuannong16.BMC Genetics. 20: 77.

[2019]Structural Organization and Functional Activity of the OrthologousTaGLW7Genes in Bread Wheat (Triticum aestivumL.).Russian Journal of Genetics. 55: 571-579.

[2019]Identification and validation of a major and stably expressed QTL for spikelet number per spike in bread wheat.Theoretical and Applied Genetics. 132: 3155–3167.

[2019]Identification and validation of a novel major QTL for all-stage stripe rust resistance on 1BL in the winter wheat line 20828.Theoretical and Applied Genetics. 132: 1363–1373.

[2018]Molecular characterization of theTaWTG1in bread wheat (Triticum aestivumL.).Gene. 678: 23-32.

[2018]Variation and diversity of the breakpoint sequences on 4AL for the 4AL/5AL translocation inTriticum.Genome. 61: 635-641.

[2018]A 55 K SNP array-based genetic map and its utilization in QTL mapping for productive tiller number in common wheat.Theoretical and Applied Genetics. 131: 2439-2450.[2017]Identification and characterization of genes on a single subgenome in the hexaploid wheat (Triticum aestivumL.) genotype ‘Chinese Spring’.Genome. 60: 208-215.

[2017]Identification of quantitative trait loci for seedling root traits from Tibetan semi-wild wheat (Triticum aestivumsubsp.tibetanum).Genome. 60: 1068-1075.

[2017]Structure and expression of theTaGW7in bread wheat (Triticum aestivumL.).Plant Growth Regulation. 82: 281-291.

[2017]Genome-wide identification and analysis of the MADS-box gene family in bread wheat (Triticum aestivumL.).PloS one. 12: e0181443.

[2016]Identification of quantitative trait loci controlling agronomic traits indicates breeding potential of Tibetan semiwild wheat (Triticum aestivumssp.tibetanum).Crop Science. 56: 2410-2420.

[2016]Genetic analysis of glume hairiness (Hg) gene in bread wheat (Triticum aestivumL.).Genetic Resources and Crop Evolution. 63: 763-769.

[2016]Structure and expression of phosphoglucan phosphatase genes ofLike Sex Four1andLike Sex Four2in barley.Genetica. 144: 313-323.

[2016]Identification of QTLs associated with tissue culture response of mature wheat embryos.Springerplus. 5: 1-7.

[2015]Putative interchromosomal rearrangements in the hexaploid wheat(Triticum aestivumL.) genotype ‘Chinese Spring’revealed by gene locations on homoeologous chromosomes.BMC Evolutionary Biology. 15: 37.

[2015]Fine mapping of a large-effect QTL conferring Fusarium crown rot resistance on the long arm of chromosome 3B in hexaploid wheat.BMC Genomics. 16: 850.

[2015]Identification of genes bordering breakpoints of the pericentric inversions on 2B, 4B and 5A in Bread Wheat (Triticum aestivumL.).Genome. 58: 1-5.

[2015]A high-throughput pipeline for detecting locus-specific polymorphism in hexaploid wheat (Triticum aestivumL.).Plant Methods. 11: 1.

[2015]Characterization of starch branching enzyme I (SBE I) gene in twoTriticum monococcumaccessions with different starch content.Starch‐St?rke.

[2014]Characterization of shrunken endosperm mutants in barley.Gene. 539: 15-20.

[2014]Extensive Pericentric Rearrangements in the Bread Wheat (Triticum aestivum L.) Genotype “Chinese Spring” Revealed from Chromosome Shotgun Sequence Data.Genome Biology and Evolution. 6: 3039-3048.

[2014]Conserved structure and varied expression reveal key roles of phosphoglucan phosphatase genestarch excess4 in barley.Planta. 240: 1179-1190.

[2014]Transcriptome and Allele Specificity Associated with a 3BL Locus for Fusarium Crown Rot Resistance in Bread Wheat.PloS one. 9: e113309.

[2013]Characterization and expression analysis ofwaxyalleles in barley accessions.Genetica. 141: 227-238.

[2013]Structure and expression of barley starch phosphorylase genes.Planta. 238: 1081-1093.

[2013]Sequence-based analysis of translocations and inversions in bread wheat (Triticum aestivumL.).PloS one. 8: e79329.

[2010]Molecular characterization and comparative analysis of twowaxyalleles in barley.Genes & Genomics. 32: 513-520.

共同作者:

[2022]Editing of the starch synthase IIa gene led to transcriptomic and metabolomic changes and high amylose starch in barley.Carbohydrate Polymers. 285: 119238.

[2022]Reference genome assemblies reveal the origin and evolution of allohexaploid oat.Nat Genet. 54: 1248-1258.

[2022]The PGS1 basic helix-loop-helix (bHLH) protein regulates Fl3 to impact seed growth and grain yield in cereals.Plant Biotechnology Journal. 1-16.

[2021]Myb10-DconfersPHS-3Dresistance to pre-harvest sprouting by regulatingNCEDin ABA biosynthesis pathway of wheat.New Phytologist.https://doi.org/10.1111/nph.17312.

[2020]Mutation of the d-hordein gene by RNA-guided Cas9 targeted editing reducing the grain size and changing grain compositions in barley.Food Chemistry. 311: 125892.

[2020]Identification and validation of stable quantitative trait loci for grain filling rate in common wheat (Triticum aestivum L.).Theoretical and Applied Genetics. 133: 2377-2385.

[2020]Phenotypic and genetic variation in phosphorus-deficiency-tolerance traits in Chinese wheat landraces.BMC Plant Biology. 20: 330.

[2020]Genome-Wide Association Study Reveals the Genetic Architecture of Stripe Rust Resistance at the Adult Plant Stage in Chinese Endemic Wheat.Frontiers in plant science. 11: 625.

[2020]Identification of lncRNAs involved in wheat tillering development in two pairs of near-isogenic lines.Functional & integrative genomics. 20: 669-679.

[2020]Quantitative trait loci analysis for root traits in synthetic hexaploid wheat under drought stress conditions.Journal of Integrative Agriculture. 19: 1947-1960.

[2019]Characterization of molecular diversity and genome-wide association study of stripe rust resistance at the adult plant stage in Northern Chinese wheat landraces.BMC Genetics. 20: 38.

[2019]Genome-wide association study reveals new loci for yield-related traits in Sichuan wheat germplasm under stripe rust stress.BMC Genomics. 20: 640.

[2019]Genome-wide association study of resistance to stripe rust (Puccinia striiformis f. sp. tritici) in Sichuan wheat.BMC Plant Biology. 19: 147.

[2019]Quantitative trait locus mapping for panicle exsertion length in common wheat using two related recombinant inbred line populations.Euphytica. 215: 104.

[2019]Genome-Wide Association Study for Adult-Plant Resistance to Stripe Rust in Chinese Wheat Landraces (Triticum aestivumL.) From the Yellow and Huai River Valleys.Frontiers in plant science. 10.

[2019]A novel QTL conferring Fusarium crown rot resistance located on chromosome arm 6HL in barley.Frontiers in plant science. 10.

[2019]Dissection of loci conferring resistance to stripe rust in Chinese wheat landraces from the middle and lower reaches of the Yangtze River via genome-wide association study.Plant Science. 287: 110204.

[2019]Comprehensive transcriptomics, proteomics, and metabolomics analyses of the mechanisms regulating tiller production in low-tillering wheat.Theoretical and Applied Genetics. 1-13.

[2019]A single-base change at a splice site in Wx-A1 caused incorrect RNA splicing and gene inactivation in a wheat EMS mutant line.Theoretical and Applied Genetics. 132: 2097-2109.

[2019]Functional Analysis of FgNahG Clarifies the Contribution of Salicylic Acid to Wheat (Triticum aestivum) Resistance against Fusarium Head Blight.Toxins. 11: 59.

[2019]Expression of the high molecular weight glutenin 1Ay gene from Triticum urartu in barley.Transgenic Research. 28: 225-235.

[2018]An overexpressedQallele leads to increased spike density and improved processing quality in common wheat (Triticum aestivum).G3: Genes, Genomes, Genetics. 8: 771-778.

[2018]Identification of QTL for flag leaf length in common wheat and their pleiotropic effects.Molecular Breeding. 38: 11.

[2018]A QTL located on chromosome 3D enhances the selenium concentration of wheat grain by improving phytoavailability and root structure.Plant and Soil. 425: 287-296.

[2017]Identification of major quantitative trait loci for root diameter in synthetic hexaploid wheat under phosphorus-deficient conditions.Journal of Applied Genetics. 58: 437-447.

[2017]A genome‐wide association study of 23 agronomic traits in Chinese wheat landraces.The Plant Journal. 91: 861-873.

[2017]Transposon insertion resulted in the silencing ofWx-B1nin Chinese wheat landraces.Theoretical and Applied Genetics. 130: 1321-1330.

[2016]Mapping and validation of major quantitative trait loci for kernel length in wild barley (Hordeum vulgaressp.spontaneum).BMC Genetics. 17.

[2016]Molecular mapping of the stripe rust resistance geneYr69on wheat chromosome 2AS.Plant Disease. 100: 1717-1724.

[2014]Characterization of high-molecular-weight glutenin subunits from Eremopyrum bonaepartis and identification of a novel variant with unusual high molecular weight and altered cysteine residues.Planta. 239: 865-875.
◆指导学生
硕士毕业24人,4人转为硕博连读;博士毕业3人;正在指导硕士12人,博士6人。

2023年:
首届袁隆平追梦奖学金:赵聪豪(全国仅9名硕士、9名博士、18名本科)
研究生国家奖学金:刘航(博士)、赵聪豪、王素容(小麦所总共推选5个)
一等学业奖学金:刘航、周界光、玄其京、赵聪豪、王素容、李伟
省级优秀毕业生:赵聪豪、王素容
校级优秀毕业生:赵聪豪、王素容、曾照勇
校级优秀研究生:周界光、刘航、玄其京、李伟


2022年:
研究生学生标兵提名奖:李聪(小麦所唯一)
研究生国家奖学金:陈黄鑫、李聪(博士)(小麦所总共4个)
一等学业奖学金:刘航、周界光、李聪、赵聪豪、尤佳宁
二等学业奖学金:王素容、杨瑶瑶、田荣、王健、谢欣霖、魏佳泰、陈黄鑫
省级优秀毕业生:刘家君、陈黄鑫
校级优秀毕业生:尤佳宁
校级优秀研究生:刘航、谢欣霖、魏佳泰、王健、赵聪豪、杨瑶瑶、王素容、田荣

2021年:
研究生国家奖学金:曲翔汝、周界光、莫自强(包揽小麦所3个指标)
一等学业奖学金:刘家君、刘航、谢欣霖、曲翔汝、周界光、莫自强
二等学业奖学金:李聪、魏佳泰、尤佳宁
省级优秀毕业生:曲翔汝
校级优秀毕业生:莫自强
校级优秀研究生:李聪、刘家君、丁浦洋
研究生中期考核及开题报告考核优秀:李聪、尤佳宁
2021年研究生优秀学术成果奖:李聪

2020年:
一等学业奖学金:涂洋、李聪、曲翔汝、刘家君、陈黄鑫
校级优秀毕业生:刘航
校级优秀研究生:涂洋、刘家君
2019年:
国家奖学金:李婷
一等学业奖学金:刘家君、丁浦洋、李婷

2018年:
四川省优秀毕业生:张涵
校级优秀研究生:杨聪聪、刘家君、秦娜娜
一等学业奖学金:罗伟、张涵、秦娜娜、刘家军
国家奖学金:张涵、刘家君
提前攻博:刘家君

2017年:
校级优秀研究生:罗伟、丁浦洋
登海奖学金:罗伟、杨宇杰
一等学业奖学金:罗伟、丁浦洋、张涵
提前攻博:丁浦洋